JP5992850B2 - Antenna switching device - Google Patents

Description

  The present disclosure relates to an antenna switching device that switches radio wave radiation characteristics in wireless communication.

  Conventionally, communication terminals that can use a wireless local area network (LAN) have become widespread with the advancement of functions of digital devices. For example, large amounts of data can be obtained by direct communication between communication terminals without using an access point. A technology for transmitting (for example, HD (High Density) video data) is attracting attention.

  However, when transmitting a large amount of data using a wireless LAN, the transmitter compresses the transmission data and the receiver decompresses the reception data, so that some delay occurs. For this reason, in an application that requires real-time, conventional video transmission in which data is compressed and decompressed each time a large amount of data is transmitted is not efficient.

  For this reason, high-speed wireless communication using millimeter waves (for example, 60 [GHz]) that can transmit uncompressed and non-delayed video data is currently attracting attention.

  Millimeter wave communication uses a wider band than wireless LAN communication. By effectively using the millimeter wave communication allowable range, for example, high-speed wireless communication of 1 [GHz] or more is possible. However, it has been pointed out that the radio wave in the millimeter wave band of 60 [GHz] is not suitable for long-distance transmission because of its short wavelength and strong straightness and being easily absorbed by oxygen molecules in the atmosphere.

  On the other hand, the communication distance can be extended by using a beam forming that electronically changes the beam direction by arranging a plurality of antenna elements and controlling the phase of the transmission radio wave and the reception radio wave in each antenna element. However, if an obstacle (for example, a human hand) is mixed between communication terminals that are performing wireless communication, communication may be interrupted.

  For example, when communication characteristics of line-of-sight communication, that is, communication using a direct wave deteriorate due to an obstacle, a wireless communication device is known that avoids communication interruption by changing the turning direction of circular polarization used for wireless communication. (For example, refer to Patent Document 1).

Japanese Patent Laid-Open No. 08-321799

  The inventor has studied an antenna switching device that switches radio wave radiation characteristics in wireless communication. However, in the above-described Patent Document 1, it is not assumed that the communication characteristics between the wireless communication device and the communication device as the communication partner change.

  For this reason, when the communication characteristics change, the antenna characteristics in wireless communication change, and it is difficult to maintain good communication characteristics in wireless communication between the wireless communication device and the communication device as the communication partner. There is a problem of becoming.

  In order to solve the above-described conventional problems, the present disclosure acquires communication characteristics with another wireless communication device as a communication partner periodically or when communication is interrupted, and the antenna radiates. An object of the present invention is to provide an antenna switching device that easily switches a wave to a polarized wave according to good communication characteristics.

The present disclosure is an antenna switching device that wirelessly communicates with another wireless communication device, and switches the polarization and beam direction in the wireless communication so that the polarization is changed in the beam direction with respect to the other wireless communication device. an antenna portion for radiating, a communication control unit that acquires the communication characteristic corresponding to the polarization and the beam direction from said another wireless communication device, the communication characteristics corresponding to the acquired polarization and the beam direction An antenna detection unit that identifies whether the type of polarization emitted from the antenna of the other wireless communication device is circular polarization or linear polarization; and the antenna of the identified other wireless communication device The antenna switching device includes an antenna switching unit that switches a polarization and a beam direction in the wireless communication with the other wireless communication device according to the type of polarization emitted from the wireless communication device.

  According to the present disclosure, when the communication is interrupted regularly or when communication is interrupted, the communication characteristic with another wireless communication device as a communication partner is acquired, and the polarization radiated by the antenna is set according to the good communication characteristic. Can be easily switched to another polarized wave.

The block diagram which shows the internal structure of the terminal device of each embodiment The figure which shows the circuit structure of an antenna part, (A) The figure which shows the circuit structure of the antenna part in the case of transmitting the packet transmission signal which the transmission part output, (B) The antenna part in the case of outputting a packet reception signal to a receiving part Figure showing the circuit configuration of The figure which shows the circuit structure of each circularly polarized wave antenna in 1st Embodiment. The figure which shows the communication path | route formed between a terminal device and another radio | wireless communication apparatus, (A) When the communication characteristic in the communication path | route between a terminal device and another radio | wireless communication apparatus does not change, (B) A terminal device is 4B, a communication path between the terminal apparatus and the other wireless communication apparatus when moving upward, and (C) a communication path between the terminal apparatus and the other wireless communication apparatus when an obstacle is mixed. Table showing the relationship between the polarization radiated by the antenna of the terminal device, the polarization radiated by the antenna of the other wireless communication device, and the communication characteristics The flowchart explaining the communication operation | movement procedure in the terminal device of 1st Embodiment. Flowchart explaining the specific operation procedure of the antenna shape of the other wireless communication device in step S1 shown in FIG. Table showing comparison results of communication characteristics for each polarization emitted from the antenna of another wireless communication device when the terminal device that sequentially switches the four beam directions uses circular polarization Table that simply shows an example of the result of communication characteristics for each beam direction periodically obtained during communication when another wireless communication apparatus has a linearly polarized antenna (A) A table simply showing an example of a result of communication characteristics for each regular beam direction during communication when the other wireless communication device has a circularly polarized antenna, and (B) the other wireless communication device is circularly polarized. A table that simply shows an example of the result of communication characteristics for each beam direction after communication interruption when an antenna is provided Comparison diagram of the number of times the beam direction is scanned in order to obtain communication characteristics after communication interruption in the prior art and the first embodiment The figure which shows the circuit structure of the polarization antenna in 2nd Embodiment. The flowchart explaining the communication operation | movement procedure in the terminal device of 2nd Embodiment. The flowchart explaining the specific operation procedure of the antenna shape of the other wireless communication apparatus in step S31 shown in FIG. Table showing comparison results of polarization radiated by antenna of other wireless communication device when terminal device uses linear polarization Comparison diagram of the number of times the beam direction is scanned in order to acquire the communication characteristics after the communication is interrupted in the conventional technique and the second embodiment

(Background to the contents of each embodiment)
First, before describing each embodiment of the antenna switching device according to the present disclosure, the problems in Patent Document 1 and Patent Document 1 described above will be described as the background to the contents of each embodiment.

  In Patent Document 1, a communication device on the backbone switch side (hereinafter referred to as “first communication device”) and a communication device on the network terminal side (hereinafter referred to as “second communication device”) communicate with each other using a wireless LAN. To do.

  The first communication device includes a plurality of antenna devices that can receive radio waves in the same turning direction as that during transmission. The second communication device includes a first antenna device that can transmit and receive circularly polarized waves in the same turning direction as the antenna devices of the first communication device, and a first antenna device that can transmit and receive circularly polarized waves having different turning directions from the first antenna device. 2 antenna devices. That is, the second communication device has an antenna device capable of adjusting two types of directivities in circular polarization.

  As a result, the communication path formed between the first communication device and the second communication device is a communication using a circularly polarized direct wave using the first antenna device or a reflected wave in which the circularly polarized wave is reflected a plurality of times. It can be distinguished into two types: a path and a communication path using a reflected wave in which circularly polarized waves using the second antenna device are reflected an odd number of times. Thereby, when communication using a direct wave becomes difficult between the first communication device and the second communication device, or when an obstacle is mixed in the communication path between the first communication device and the second communication device. However, by switching to a reflected wave in which circularly polarized waves are reflected an odd number of times, communication can be performed while suppressing the influence of multipath.

  However, in Patent Document 1, it is considered that the case where the communication characteristics between the first communication device and the second communication device change is not considered. For example, when the first communication device and the second communication device perform wireless communication using a millimeter-wave high-frequency signal, the second communication device moves or an obstacle (between the first communication device and the second communication device). For example, when human hands are mixed, wireless communication between the first communication device and the second communication device is easily interrupted.

  Actually, when the wireless communication between the first communication device and the second communication device is interrupted, it is necessary to acquire the communication characteristics between the first communication device and the second communication device before starting the wireless communication. is there. Specifically, the first communication device and the second communication device acquire the communication characteristics with each other's communication partner through a plurality of trial communications, and the radio waves (polarized waves) radiated from the antenna can be transmitted in good communication. Switching to polarized waves (for example, circularly polarized waves or linearly polarized waves) according to the characteristics.

  For this reason, if the wireless communication between the first communication device and the second communication device is interrupted, the number of trial communications in the first communication device and the second communication device increases, so the first communication device and the second communication device. There has been a problem that power consumption in the apparatus increases.

  Therefore, in each of the following embodiments, when communication is interrupted periodically or when communication is interrupted, communication characteristics with another wireless communication device as a communication partner are acquired, and the polarization radiated by the antenna is improved. An example of an antenna switching device that easily switches to polarized waves according to characteristics will be described.

  Next, each embodiment of the antenna switching device according to the present disclosure will be described with reference to the drawings. Hereinafter, an example of the antenna switching device according to the present disclosure will be described as a terminal device that wirelessly communicates with another wireless communication device as a communication partner, and for the sake of simplicity, the other wireless communication device is stationary. Machine (for example, a TV device). The terminal device of each embodiment performs wireless communication using, for example, 60 [GHz] millimeter-wave radio waves (polarized waves).

(First embodiment)
In the first embodiment, the terminal device 60 switches and emits a circularly polarized wave in the left-turning direction and a circularly polarized wave in the right-turning direction in a millimeter wave band of 60 [GHz], for example. The other wireless communication device 50 transmits a millimeter-wave packet transmission signal.

  FIG. 1 is a block diagram showing an internal configuration of the terminal device 60 of each embodiment. A terminal device 60 shown in FIG. 1 includes an antenna unit 61, a transmission unit 62, a reception unit 63, a communication control unit 64, an antenna detection unit 65, and an antenna switching unit 66.

  In the wireless communication with the other wireless communication device 50, the antenna unit 61 performs the circularly polarized turning direction (left turning direction, right turning direction) and beam direction according to the antenna switching control signal generated by the antenna switching unit 66. , Transmit packet transmission signal using circular polarization in left turn direction or right turn direction, and receive packet reception signal transmitted using circular polarization in left turn direction or right turn direction To do.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 displays, for example, communication characteristics with another wireless communication device 50 (for example, SN: Signal to Noise ratio, signal-to-noise ratio, and so on). A packet transmission signal for requesting is generated and output to the antenna unit 61.

  The reception unit 63 receives the packet reception signal returned from the other wireless communication device 50 from the antenna unit 61, demodulates the packet reception signal, and outputs the demodulation result of the packet reception signal to the communication control unit 64 or the antenna detection unit 65. .

  When the terminal device 60 performs wireless communication with the other wireless communication device 50, the communication control unit 64 generates a communication property acquisition request for requesting a communication property (for example, SN) with the other wireless communication device 50, for example. To the transmitter 62.

  The communication control unit 64 instructs the antenna switching unit 66 to switch the turning direction and beam direction of the circularly polarized wave, and further, based on the demodulation result of the packet reception signal in the receiving unit 63, the communication control unit 64 communicates with the other radio communication device 50. Get communication characteristics of. The communication control unit 64 stores the demodulation result of the packet reception signal demodulated by the reception unit 63 in a memory (not shown).

  The antenna detection unit 65 stores the demodulation result of the packet reception signal demodulated by the reception unit 63 in a memory (not shown), and further determines the demodulation result of the packet reception signal, that is, the communication characteristics with the other wireless communication device 50. Based on this, it is specified whether the antenna shape of the other wireless communication device 50 is a circularly polarized antenna or a linearly polarized antenna. That is, the antenna detection unit 65 specifies whether the type of polarization emitted by the antenna of the other wireless communication device 50 is circular polarization or linear polarization.

  The antenna detection unit 65 determines that the turning direction of the polarization plane of the circularly polarized wave radiated from the circularly polarized antenna is left-turned or right-turned when the antenna shape of the other wireless communication device 50 is specified as a circularly polarized antenna. Specify which direction is the turning direction. The antenna detection unit 65 outputs the identification result of the turning direction of the polarization plane of circular polarization to the communication control unit 64 or the antenna switching unit 66.

  The antenna switching unit 66 outputs an antenna switching control signal for switching the turning direction and the beam direction of the polarization plane of the circularly polarized wave in accordance with an instruction from the communication control unit 64 or a result of specifying the type of polarization in the antenna detection unit 65. Generated and output to the antenna unit 61. That is, the antenna switching unit 66 causes the antenna unit 61 to switch between the turning direction of the polarization plane of circular polarization and the beam direction indicating the direction of the main beam of circular polarization.

  FIG. 2 is a diagram illustrating a circuit configuration of the antenna unit 61. FIG. 2A is a diagram illustrating a circuit configuration of the antenna unit 61A when the packet transmission signal output from the transmission unit 62 is transmitted. FIG. 2B is a diagram illustrating a circuit configuration of the antenna unit 61 </ b> B when a packet reception signal is output to the receiving unit 63.

  An antenna section 61A shown in FIG. 2A includes a plurality of circularly polarized antennas 71A, a plurality of amplifiers (amplifiers) 72, and a plurality of variable phase shifters 73. A packet transmission signal generated by the transmission unit 62 is distributed and input to each variable phase shifter 73. The antenna unit 61A may have a configuration other than that shown in FIG. 2A, and is configured using elements other than the plurality of circularly polarized antennas 71A, the plurality of amplifiers (amplifiers) 72, and the plurality of variable phase shifters 73. May be. In addition, the main beam direction is switched by the antenna unit 61A. However, the main beam direction may be switched by changing the phase in the baseband band instead of the RF (radio frequency band) and connecting to the circularly polarized antenna 71A. good.

  An antenna unit 61B shown in FIG. 2B includes a plurality of circularly polarized antennas 71B, a plurality of amplifiers (amplifiers) 74, and a plurality of variable phase shifters 75. A packet reception signal as an output of each variable phase shifter 75 is synthesized and input to the reception unit 63. The antenna unit 61B may have a configuration other than that shown in FIG. 2B, and is configured using elements other than the plurality of circularly polarized antennas 71B, the plurality of amplifiers (amplifiers) 74, and the plurality of variable phase shifters 75. May be. In addition, the main beam direction is switched by the antenna unit 61A. However, the main beam direction may be switched by changing the phase in the baseband band instead of the RF (radio frequency band) and connecting to the circularly polarized antenna 71B. good.

  In the antenna unit 61A shown in FIG. 2A, for example, four circularly polarized antennas 71A are provided, and the same number of amplifiers 72 and variable phase shifters 73 as the circularly polarized antennas 71A are provided. Similarly, in the antenna unit 61B shown in FIG. 2B, for example, four circularly polarized antennas 71B are provided, and the same number of amplifiers 74 and variable phase shifters 75 as the circularly polarized antennas 71B are provided.

  Each variable phase shifter 73 gives a different phase amount to each packet transmission signal output from the transmission unit 62 according to the antenna switching control signal generated by the antenna switching unit 66 and outputs the packet transmission signal to each amplifier 72. Thereby, the antenna unit 61A can switch the direction of the transmission beam for transmitting the packet transmission signal radiated from each circularly polarized antenna 71.

  Each amplifier 72 amplifies the packet transmission signal to which each variable phase shifter 73 has a different phase amount and outputs the amplified signal to each circularly polarized antenna 71A.

  The circularly polarized antenna 71A feeds the power of the packet transmission signal amplified by each amplifier 72, and the circularly polarized wave in the left turn direction or the right turn direction according to the antenna switching control signal generated by the antenna switching unit 66. A packet transmission signal is transmitted by radiating.

  The circularly polarized antenna 71B receives a packet reception signal transmitted as a circularly polarized wave in the left turn direction or the right turn direction according to the antenna switching control signal generated by the antenna switching unit 66, and outputs it to each amplifier 74. To do.

  Each amplifier 74 amplifies the packet reception signal received by each circularly polarized antenna 71 </ b> B and outputs the amplified signal to each variable phase shifter 75.

  Each variable phase shifter 75 gives a different phase amount to the packet reception signal amplified by each amplifier 74 according to the antenna switching control signal generated by the antenna switching unit 66 and outputs the packet reception signal to the receiving unit 63. Thereby, the antenna unit 61B can switch the direction of the reception beam for receiving, for example, a packet reception signal transmitted by the other wireless communication device 50. In the following description, the beam direction including the transmit beam direction and the receive beam direction is simply described.

  FIG. 3 is a diagram illustrating a circuit configuration of each of the circularly polarized antennas 71A and 71B in the first embodiment. The circularly polarized antennas 71A and 71B shown in FIG. 3 are, for example, a two-point fed circularly polarized patch antenna, a two-terminal fed circularly polarized antenna 91, a 90-degree phase shifter 92, and a 180-degree hybrid 93. including.

  The two-terminal feed type circularly polarized wave antenna 91 has two input / output terminals 91a and 91b as power supply terminals, and power of two signals with a phase difference of 90 degrees is fed to each of the input / output terminals 91a and 91b. In addition, circularly polarized waves in the left turn direction or the right turn direction are radiated.

  When the packet transmission signal amplified by the amplifier 72 is input to the input terminal 93a, the 180-degree hybrid 93 generates two packet transmission signals having a phase difference of 180 degrees and an amplitude of ½ times. Output to the pair of input / output terminals 93c and 93d. The 180-degree hybrid 93 synthesizes two packet reception signals when two packet reception signals having a phase difference of 0 degree are input to the pair of input / output terminals 93c and 93d, and outputs the combined packet reception signal to an output terminal. The signal is output to the amplifier 74 via 93b.

  The 90-degree phase shifter 92 is connected between the input / output terminal 93 d of the 180-degree hybrid 93 and the input / output terminal 91 b of the two-terminal feed circularly polarized antenna 91. The 90-degree phase shifter 92 is connected between the input / output terminal 93d of the 180-degree hybrid 93 and the input / output terminal 91b of the two-terminal feed circularly polarized antenna 91 according to the antenna switching control signal generated by the antenna switching unit 66. The phase of the signal is advanced or delayed by 90 degrees.

  When a packet transmission signal is transmitted by the circularly polarized antenna 71A shown in FIG. 3, the signal power of the packet transmission signal input to the 180-degree hybrid 93 via the input terminal 93a is distributed into two signal powers. One signal power is fed to the input / output terminal 91a of the two-terminal feed circularly polarized antenna 91, and the other signal power is fed to the input / output terminal 91b via the 90-degree phase shifter 92.

  The phase difference between the signal powers fed to the two input / output terminals 91a and 91b of the two-terminal feed type circularly polarized antenna 91 is 90 degrees. Accordingly, the two-terminal-feed circularly polarized antenna 91 has a phase difference of 90 degrees (for example, −90 degrees or +90 degrees) in the 90-degree phase shifter 92 in accordance with the antenna switching control signal generated by the antenna switching unit 66. Is switched to radiate circularly polarized waves in the left turn direction or the right turn direction.

  For example, if the phase difference between the two signals input to the two-terminal-feed type circularly polarized antenna 91 is −90 degrees, the circularly polarized antenna 71A radiates a circularly polarized wave in the left-turn direction, and If the phase difference is +90 degrees, circularly polarized waves in the right turn direction are emitted.

  On the other hand, when a packet reception signal is received by the circularly polarized antenna 71B shown in FIG. 3, the other radio communication device 50 transmits the packet reception signal from the input / output terminals 91a and 91b of the two-terminal-feed type circularly polarized antenna 91. Two signals having the same turning direction as the current turning direction, that is, the same phase difference of 90 degrees (for example, -90 degrees or +90 degrees) are output.

  One signal is input to the input / output terminal 93c of the 180-degree hybrid 93, and the other signal is input to the input / output terminal 93d of the 180-degree hybrid 93 via the 90-degree phase shifter 92. The 180-degree hybrid 93 synthesizes the phase difference between the two signals input to the input / output terminals 93c and 93d so as to be 0 degree and outputs the resultant to the output terminal 93b.

  Note that the circularly polarized antennas 71A and 71B may have different configurations from those in FIG. 3, and when transmitting, if the phase relationship between the input / output terminals 91a and 91b is appropriate, and when receiving, 93c, If the phase relationship of 93d is appropriate, elements other than the input / output terminal 2-terminal-feed circular polarization antenna 91, the 90-degree phase shifter 92, and the 180-degree hybrid 93 may be used.

  FIG. 4 is a diagram illustrating a communication path formed between the terminal device 60 and the other wireless communication device 50. FIG. 4A shows a case where the communication characteristics in the communication path between the terminal device 60 and the other wireless communication device 50 do not change.

  In FIG. 4A, the terminal device 60 and the other wireless communication device 50 are arranged to face each other. In FIG. 4, in order to simplify the description, the terminal device 60 and the other wireless communication device 50 sequentially switch the four beam directions, and each beam direction is “1, 2, 3, 4” in order from the top in the figure. It describes.

  A communication path 51a shown in FIG. 4A is a communication path using a direct wave. For example, in the communication path 51a using the direct wave shown in FIG. 4A, the beam direction in which the best communication characteristic is obtained is the line-of-sight communication between the terminal device 60 and the other wireless communication device 50, that is, the communication in which the direct wave reaches. Is the beam direction corresponding to the beam number 2 possible.

  A communication path 51b illustrated in FIG. 4A is a communication path using a reflected wave. For example, in the communication path 51b using the reflected wave shown in FIG. 4A, the beam direction that provides the best communication characteristics is the beam direction corresponding to the beam number 4.

  FIG. 4B shows a communication path between the terminal device 60 and the other wireless communication device 50 when the terminal device 60 moves upward in FIG. 4B. A communication path 52a shown in FIG. 4B is a communication path using a direct wave. The terminal apparatus 60 uses the beam direction corresponding to the beam number 3, and the other radio communication apparatus 50 uses the beam corresponding to the beam number 1. The best communication characteristics are obtained when the direction is used.

  A communication path 52b illustrated in FIG. 4B is a communication path using a reflected wave. For example, the best communication characteristics can be obtained when the terminal device 60 uses the beam direction corresponding to the beam number 4 and the other wireless communication device 50 uses the beam direction corresponding to the beam number 4.

  FIG. 4C shows a communication path between the terminal device 60 and the other wireless communication device 50 when the obstacle 54 is mixed. When an obstacle 54 (for example, a human hand) is mixed between the terminal device 60 and the other wireless communication device 50, a direct wave from the terminal device 60 does not reach the other wireless communication device 50 (FIG. 4C). Communication path 51a shown).

  In FIG. 4C, the obstacle 54 does not enter the communication path 51b using the reflected wave. Therefore, in the communication path 51b shown in FIG. 4C, when the terminal device 60 uses the beam direction corresponding to the beam number 4 and the other wireless communication device 50 uses the beam direction corresponding to the beam number 4, The best communication characteristics can be obtained.

  FIG. 5 is a table showing the relationship between the polarization radiated by the antenna of the terminal device 60, the polarization radiated by the antenna of the other radio communication device 50, and the communication characteristics.

  When the antenna unit 61 of the terminal device 60 and the antenna of the other wireless communication device 50 radiate linearly polarized waves as in patterns 1 and 4 shown in FIG. If the polarizations match, the communication characteristics between the terminal device 60 and the other wireless communication device 50 are good. For example, when the terminal device 60 and the other wireless communication device 50 use vertically polarized waves, the communication characteristics between the terminal device 60 and the other wireless communication device 50 are good.

  On the other hand, when the polarization planes of the linearly polarized waves are different by 90 degrees as in patterns 2 and 3 shown in FIG. 5, the terminal device 60 and the other wireless communication device 50 have a communication failure. For example, when the terminal device 60 radiates vertical polarization and the other radio communication device 50 radiates horizontal polarization, the terminal device 60 and the other radio communication device 50 have poor communication.

  Further, as in patterns 5, 6, 7, and 8 shown in FIG. 5, one of the antenna unit 61 of the terminal device 60 and the antenna of the other wireless communication device 50 radiates linearly polarized waves, and the other radiates circularly polarized waves. In this case, the received power is halved (1/2), but the communication characteristics between the terminal device 60 and the other wireless communication device 50 are good even if the other wireless communication device 50 and the terminal device 60 rotate. For example, when the terminal device 60 radiates vertically polarized waves and the other wireless communication device 50 radiates circularly polarized waves in the clockwise direction as in the pattern 5 shown in FIG. The signal power with the communication device 50 is halved, but the communication characteristics are good even if the other wireless communication device 50 and the terminal device 60 rotate.

  In addition, when the antenna unit 61 of the terminal device 60 and the antenna of the other wireless communication device 50 also radiate circularly polarized waves as in patterns 9 and 12 shown in FIG. Or the right turn direction) matches, the communication characteristics between the terminal device 60 and the other wireless communication device 50 are good. For example, when each antenna of the terminal device 60 and the other wireless communication device 50 uses circular polarization in the right turn direction, the communication characteristics between the terminal device 60 and the other wireless communication device 50 are good.

  On the other hand, when the turning directions of the circularly polarized waves are different as in the patterns 10 and 11 shown in FIG. 5, the terminal device 60 and the other wireless communication device 50 have poor communication. For example, when the terminal device 60 radiates a circularly polarized wave in the right turn direction and the other wireless communication device 50 radiates a circularly polarized wave in the left turn direction, the terminal device 60 and the other wireless communication device 50 communicate with each other. It becomes defective.

(Communication operation procedure of terminal device 60)
Next, a communication operation procedure in the terminal device 60 of the present embodiment will be described with reference to FIG. FIG. 6 is a flowchart illustrating a communication operation procedure in the terminal device 60 according to the first embodiment. In the description of FIG. 6, it is assumed that the antenna unit 61 of the terminal device 60 radiates circularly polarized waves in the left turn direction or the right turn direction.

  In FIG. 6, the communication control unit 64 determines that the antenna shape of the other radio communication device 50, that is, the antenna of the other radio communication device 50, before the radio communication between the terminal device 60 and the other radio communication device 50 is started. The type of polarized wave to be radiated is specified (see FIG. 7). Specifically, the communication control unit 64 causes the antenna switching unit 66 to switch the turning direction and beam direction of the circularly polarized wave radiated from the antenna unit 61, and sets the communication characteristics for each beam direction in the circularly polarized wave in both turning directions. Obtain (S1).

(Specific operation procedure of antenna shape of other wireless communication device 50)
FIG. 7 is a flowchart for explaining the specific operation procedure of the antenna shape of the other wireless communication device 50 in step S1 shown in FIG.

  In FIG. 7, for example, the communication control unit 64 switches the circular polarization turning direction radiated by the antenna unit 61 to the right turning direction, and further instructs the antenna switching unit to switch the circularly polarized beam direction in the right turning direction. In addition, a communication characteristic acquisition request for requesting communication characteristics with the other wireless communication device 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the turning direction of the circular polarization radiated from the antenna unit 61 to the right turning direction, and further switches the beam direction of the circular polarization in the right turning direction. Antenna switching control signal is generated and output to the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmission unit 62 for every beam direction using circular polarization in the clockwise direction. (S11).

  When the other wireless communication device 50 receives the packet transmission signal transmitted using the circularly polarized wave in the right turn direction, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 receives a packet reception signal from the other wireless communication device 50 (S12, YES), the terminal device 60 outputs the packet reception signal to the reception unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the antenna detection unit 65.

  The antenna detection unit 65 stores information indicating communication characteristics with the other wireless communication device 50 in a memory (not shown) for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63 (S13). . That is, the antenna detection unit 65 stores information indicating communication characteristics for all beam directions when circular polarization in the right turn direction is used, and the communication control unit 64 performs the next operation, that is, in the left turn direction. Instructs acquisition of information indicating communication characteristics for all beam directions when circular polarization is used.

  In addition, the other wireless communication device 50 returns the information indicating the communication characteristic in the beam direction in which the best communication characteristic is obtained or the information in the beam direction in which the best communication characteristic is obtained in the packet reception signal and returning it. In this case, the antenna detection unit 65 may store information indicating the communication characteristics in the beam direction in which the best communication characteristics are obtained or information on the beam directions in which the best communication characteristics are obtained. The same applies to the embodiment.

  On the other hand, if no reply is received from another wireless communication device 50 after a certain period of time has elapsed since the terminal device 60 transmitted a packet transmission signal for each beam direction (S12, NO), the antenna detection unit 65 returns a reply. Is stored for each corresponding beam direction (S14), and the communication control unit 64 performs the next operation, that is, for each beam direction in the case of using a left-turn circular polarization. Instructs acquisition of information indicating communication characteristics.

  Next, the communication control unit 64 outputs to the antenna switching unit 66 an instruction to switch the turning direction of the circularly polarized wave radiated from the antenna unit 61 to the leftward turning direction, and to switch the beam direction of the circularly polarized wave in the leftward turning direction. Furthermore, a communication characteristic acquisition request for requesting communication characteristics with the other wireless communication device 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the turning direction of the circularly polarized wave radiated from the antenna unit 61 to the left turning direction, and further switches the beam direction of the circularly polarized wave in the left turning direction. An antenna switching control signal is generated and output to the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmission unit 62 for every beam direction using circular polarization in the left-turn direction ( S15).

  When the other wireless communication device 50 receives the packet transmission signal transmitted using the circularly polarized wave in the left turn direction, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 receives the packet reception signal from the other wireless communication device 50 (S16, YES), the terminal device 60 outputs the packet reception signal to the reception unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the antenna detection unit 65.

  The antenna detection unit 65 stores information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 in a memory (not shown) for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63. (S17). That is, the antenna detection unit 65 stores information indicating communication characteristics for every beam direction when circular polarization in the left turn direction is used. Thereby, the specific operation procedure of the antenna shape of the other wireless communication device 50 shown in FIG. 7 is completed, and the communication operation procedure of the terminal device 60 returns to step S2 of the flowchart shown in FIG.

  On the other hand, if no reply is received from another wireless communication device 50 after a certain period of time has elapsed since the terminal device 60 transmitted a packet transmission signal for each beam direction (S16, NO), the antenna detector 65 returns a reply. There is no information, i.e., information indicating that it has not been received, for each corresponding beam direction (S18). Thereby, the specific operation procedure of the antenna shape of the other wireless communication device 50 shown in FIG. 7 is completed, and the communication operation procedure of the terminal device 60 returns to step S2 of the flowchart shown in FIG.

  In FIG. 7, the terminal device 60 first radiates a circularly polarized wave in the right turn direction, and then radiates a circularly polarized wave in the left turn direction. However, the order of the turn directions is the left turn direction and the right turn direction. Either of the turning directions may be first.

  In FIG. 6, the antenna detection unit 65 includes information indicating communication characteristics for each beam direction when circular polarization in the right turn direction is used, and information for each beam direction when circular polarization in the left turn direction is used. Compare with information indicating communication characteristics.

  The antenna detection unit 65 indicates information indicating communication characteristics for each beam direction when using circular polarization in the right turn direction, and indicates communication characteristics for each beam direction when using circular polarization in the left turn direction. Based on the comparison result with the information, it is specified whether the antenna shape of the other wireless communication device 50 is a circularly polarized antenna or a linearly polarized antenna (S2).

  FIG. 8 is a table showing a comparison result of communication characteristics for each polarization emitted from the antenna of the other wireless communication device 50 when the terminal device 60 that sequentially switches the four beam directions uses circular polarization. In FIG. 8, the terminal device 60 uses the respective circularly polarized waves in the left turn direction and the right turn direction, and the other wireless communication device 50 switches the beam direction using the linearly polarized wave and the circularly polarized wave. The comparison results of the beam directions in which various communication characteristics were obtained are shown. Numerical values (for example, 2 and 4) shown in FIG. 8 represent beam numbers in the beam direction in which the best communication characteristics are obtained (see FIG. 4).

  Specifically, the antenna detection unit 65 determines that the difference in communication characteristics between the terminal device 60 and the other wireless communication device 50 is within a predetermined range when the circularly polarized waves in the left turn direction and the right turn direction are used. Or when the beam numbers in the beam direction in which the best communication characteristics are obtained are the same (see column 501 shown in FIG. 8), the antenna shape of the other wireless communication device 50 is a linearly polarized antenna. Identify.

  This means that when the circularly polarized wave is received as a linearly polarized wave or when the linearly polarized wave is received as a circularly polarized wave, the power is theoretically halved (see FIG. 5), but it turns right. This is because the circular polarization in the direction and the circular polarization in the left-turn direction are received as the same communication characteristics.

  In addition, in communication using a direct wave (see communication path 51a in FIG. 4) or a reflected wave (see communication path 51b in FIG. 4), the polarization plane does not change even if the linearly polarized wave is reflected on the wall or the ground. For this reason, if the antenna shape of the other wireless communication device 50 is a linearly polarized antenna, the same communication characteristics can be obtained regardless of whether the circularly polarized wave in the clockwise direction or the circularly polarized wave in the counterclockwise direction is radiated.

  On the other hand, the antenna detection unit 65 has a communication characteristic difference between the terminal device 60 and the other wireless communication device 50 that is not within a predetermined range when the circularly polarized waves in the left turn direction and the right turn direction are used. If the beam number in the beam direction in which good communication characteristics are obtained is different (see column 502 shown in FIG. 8), or if there is no response to the circularly polarized radiation in the left turn direction or the right turn direction, other wireless communication The antenna shape of the device 50 is specified as a circularly polarized antenna.

  This is because once the circularly polarized wave is reflected on the wall or the ground, the turning direction changes. For example, a circularly polarized wave in the left turn direction is changed to a circularly polarized wave in the right turn direction by one reflection, and a circularly polarized wave in the right turn direction is changed to a circularly polarized wave in the left turn direction by one reflection. In addition, when the circularly polarized wave is reflected on the wall or the ground even number of times, the turning direction returns to the original turning direction.

  For example, when the antenna shape of the other wireless communication device 50 is a circularly polarized antenna that radiates circular polarization in the clockwise direction, and the terminal device 60 radiates circular polarization in the clockwise direction, the other wireless communication device 50 Can receive a direct wave (see the communication path 51a in FIG. 4) or a reflected wave reflected an even number of times. The other wireless communication device 50 can send back a packet transmission signal including communication characteristics of a direct wave or a reflected wave reflected even times. Since the other radio communication device 50 radiates the circularly polarized wave in the right turning direction, the terminal device 60 can receive the direct wave or the reflected wave reflected even times.

  Further, when the terminal device 60 radiates a circularly polarized wave in the left turn direction, the other wireless communication device 50 can receive the circularly polarized wave in the right turn direction, and therefore receives the circularly polarized wave in the left turn direction. Although it is difficult, it can receive reflected waves that have been reflected an odd number of times. The other wireless communication device 50 can send back a packet transmission signal including the communication characteristics of the reflected wave reflected an odd number of times. Since the other wireless communication device 50 radiates the circularly polarized wave in the clockwise direction, the terminal device 60 can receive the reflected wave that has been reflected an odd number of times.

  Accordingly, the antenna detection unit 65 determines whether the antenna shape of the other radio communication device 50 is a circularly polarized antenna or a linearly polarized antenna, that is, the polarization radiated from the antenna of the other radio communication device 50 is circularly polarized or linear. It is possible to easily identify whether it is a polarized wave. In addition, although the case where the other wireless communication apparatus 50 has the circularly polarized antenna that radiates the circularly polarized wave in the right turn direction has been described, the same applies to the case where the other wireless communication device 50 has the left turn antenna.

  The antenna detection unit 65 specifies the antenna shape of the other wireless communication device 50, and then outputs the specification result to the communication control unit 64. The communication control unit 64 instructs the antenna switching unit 66 to switch the turning direction and the beam direction of the circularly polarized wave according to the result of specifying the antenna shape of the other radio communication device 50, and the terminal device 60 and the other radio communication device 50. Starts communication with.

  The specific operation procedure of the antenna shape in step S1 may be performed periodically during sleep, for example, before the communication between the terminal device 60 and the other wireless communication device 50 is started. The same applies to the form.

(Communication operation procedure when other wireless communication device 50 has a linearly polarized antenna)
The case where the communication characteristics change during the communication between the terminal device 60 and the other wireless communication device 50 is, for example, the case where the terminal device 60 moves (see FIG. 4B), or the terminal device 60 and the other wireless communication device 50. It is conceivable that the obstacle 54 is mixed between the two (see FIG. 4C).

  In order to simplify the following description, the case where the terminal device 60 moves will be described. However, the case where the other wireless communication device 50 moves or the case where both the terminal device 60 and the other wireless communication device 50 move also occurs. It is the same.

  When the communication control unit 64 specifies that the antenna shape of the other radio communication device 50 is a linearly polarized antenna (S2, YES), the communication control unit 64 determines the turning direction of the circularly polarized wave radiated by the antenna unit 61 most in step S1. An instruction to switch to the direction of circular polarization with good communication characteristics (for example, the direction of right turn), and to switch to the direction of circular polarization with the best communication characteristics of the right turn direction. It outputs to the antenna switching part 66, and communication is started (S2-1).

  Thereafter, in step S3, as shown in FIG. 4, the communication control unit 64 takes into account a change in communication characteristics between the other wireless communication device 50 and the terminal device 60 at a predetermined time interval. A communication characteristic acquisition request for requesting communication characteristics with another wireless communication device 50 is generated and output to the transmission unit 62.

  In step S3, the antenna switching unit 66 does not switch the turning direction of the circularly polarized wave radiated from the antenna unit 61 even when the communication control unit 64 instructs. This is because the other wireless communication device 50 is linearly polarized and there is no change in communication characteristics depending on the turning direction.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. .

  In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 uses the circularly polarized wave in the right turning direction that is the same turning direction communicated in step S2-1, and the transmitting unit 62 The generated packet transmission signal is transmitted for every beam direction.

  Next, in step S4, when the terminal device 60 moves, the other wireless communication device 50 has an obstacle 54 mixed between the communication paths 52a and 52b or between the terminal device 60 and the other wireless communication device 50. The packet transmission signal transmitted from the terminal device 60 is received via the communication path 51b.

  When the other wireless communication device 50 receives the packet transmission signal transmitted using the circularly polarized wave in the right turn direction, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 moves, the terminal device 60 communicates with other wireless devices via the communication routes 52a and 52b, or when the obstacle 54 is mixed between the terminal device 60 and the other wireless communication device 50, through the communication route 51b. The packet transmission signal transmitted by the communication device 50 is received.

  The terminal device 60 outputs the packet reception signal received from the other wireless communication device 50 to the receiving unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the communication control unit 64.

  The communication control unit 64 acquires information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63 and stores the information in a memory (not shown). ) To obtain the SN for each beam direction. An instruction to switch the antenna to a beam direction better than the acquired SN is output to the antenna switching unit 66. The antenna switching unit 66 controls the antenna unit 61 based on the antenna switching instruction.

  Thereafter, the communication control unit 64 repeats each operation of step S3 and step S4.

  Thereby, the communication control part 64 can monitor the communication characteristic between the terminal device 60 and the other radio | wireless communication apparatus 50, and can avoid a packet loss. Further, since the terminal device 60 can specify that the antenna shape of the other radio communication device 50 is a linearly polarized antenna, a packet transmission signal for acquiring communication characteristics with the other radio communication device 50 is obtained in step S1. In this case, it is only necessary to transmit the circularly polarized wave with respect to the turning direction (either the left turning direction or the right turning direction) of the circularly polarized wave in which the best communication characteristics are obtained.

  The beam direction used for communication can be selected as long as it is good in addition to the direction with the best communication characteristics.

  Accordingly, when the terminal device 60 starts communication between the terminal device 60 and the other wireless communication device 50, the terminal device 60 switches to the circular polarization in both the left turning direction and the right turning direction. Since there is no need to acquire communication characteristics with the other wireless communication device 50, power consumption required for acquiring communication characteristics with the other wireless communication device 50 can be reduced, and communication with the other wireless communication device 50 can be easily started. it can.

  When the communication control unit 64 detects deterioration of communication characteristics or packet loss at regular time intervals, the communication control unit 64 turns the packet transmission signal for acquiring the communication characteristics in the same turning direction as the turning direction in communication for each beam direction. You may transmit using the circular polarization of a direction.

  FIG. 9 is a table simply showing an example of the result of the communication characteristics for each beam direction periodically obtained during communication when the other wireless communication device 50 has a linearly polarized antenna. Note that FIG. 9 shows a case where the beam direction is 16 directions. The beam directions are not limited to the four directions shown in FIG. 4 and the 16 directions shown in FIG. 9, and any number can be used.

  FIG. 9 shows the result of switching (scanning) the beam directions of the circularly polarized waves in both turning directions from beam numbers 1 to 16 during the communication of a predetermined time before the present. The communication characteristics in the beam direction of the polarized beam No. 1 were the best (see the left side of the arrow shown in FIG. 9).

  In FIG. 9, since the terminal device 60 can specify that the antenna shape of the other radio communication device 50 is a linearly polarized antenna, the right turn with which the best communication characteristics have been obtained during the communication at the predetermined time before is currently obtained. By switching between the direction and the beam direction, the communication characteristics with the other wireless communication device 50 are acquired. In FIG. 9, the communication characteristic in the beam direction corresponding to the beam number 15 using the circularly polarized wave in the right turn direction is the best (see the right side of the arrow shown in FIG. 9).

  Since the beam direction in which the best communication characteristics are obtained without changing the turning direction of the circularly polarized wave is different, the terminal device 60 can detect the movement of the terminal device 60 itself, and instead of the both turning directions, the turning direction ( For example, the beam direction in the circularly polarized wave in the clockwise direction in FIG. 9 is scanned.

  As a result, the terminal device 60 can specify that the antenna shape of the other wireless communication device 50 is a linearly polarized antenna, so that the terminal device 60 does not rotate in both directions but in a single direction (for example, the right direction in FIG. 9). By scanning the wave beam direction, it is possible to reduce the power consumption required to acquire the communication characteristics with the other wireless communication device 50.

(Communication operation procedure when other wireless communication device 50 has a circularly polarized antenna)
1. When Terminal Device 60 Moves First, a communication operation procedure of the terminal device 60 when the terminal device 60 moves during the communication between the terminal device 60 and the other wireless communication device 50 (see FIG. 4B) will be described. . In the following description, it is assumed that the antenna of the other wireless communication device 50 radiates, for example, a circularly polarized wave in the clockwise direction.

When the communication control unit 64 specifies that the antenna shape of the other wireless communication device 50 is a circularly polarized antenna (S2, NO),
The turning direction of the circularly polarized wave radiated by the antenna unit 61 is switched to the turning direction of the circularly polarized wave (for example, the rightward turning direction) in which the best communication characteristics were obtained in step S1, and the most rightward direction of the right turning direction. An instruction to switch to a circularly polarized beam direction with good communication characteristics is output to the antenna switching unit 66, and communication is started (S2-2).

  Thereafter, in step S5, as shown in FIG. 4, the communication control unit 64 takes into account a change in communication characteristics between the other wireless communication device 50 and the terminal device 60 at a predetermined time interval. A communication characteristic acquisition request for requesting communication characteristics with the other wireless communication device 50 is generated and output to the transmission unit 62 (S5).

  In step S5, the antenna switching unit 66 does not switch the turning direction of the circularly polarized wave emitted by the antenna unit 61 even when the communication control unit 64 instructs. Because the other wireless communication device 50 is circularly polarized, there is a change in communication characteristics depending on the turning direction. However, depending on the cause of communication interruption, the number of beam direction scans (switching of the turning direction) can be reduced.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 uses the circularly polarized wave in the right turning direction that is the same turning direction communicated in step S2-2, and the transmitting unit 62 The generated packet transmission signal is transmitted for every beam direction.

  Next, in step S6, when the terminal device 60 moves, the other wireless communication device 50 receives the packet transmission signal transmitted by the terminal device 60 through the communication path 52a (see FIG. 4B).

  However, in order to simplify the explanation, the antenna of the other radio communication device 50 is a circularly polarized antenna that radiates a circularly polarized wave in the right turn direction. In this case, the packet transmission signal transmitted by the terminal device 60 can be received through the communication path 52a. In the communication path 52b, the circularly polarized wave in the rightward turning direction is once reflected on the ground, and then changed into the circularly polarized wave in the leftward turning direction, which makes it difficult for the antenna of the other wireless communication device 50 to receive.

  When the other wireless communication device 50 receives the packet transmission signal transmitted using the circularly polarized wave in the right turn direction, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  In addition, when the terminal device 60 moves, the terminal device 60 receives the packet reception signal transmitted by the other wireless communication device 50 through the communication path 52a (see FIG. 4B).

  However, since the antenna of the other wireless communication device 50 is a circularly polarized antenna that radiates a circularly polarized wave in the right-turn direction, the terminal device 60 can be changed by the communication path 52a when the terminal device 60 moves. The packet reception signal transmitted by the other wireless communication device 50 can be received.

  The terminal device 60 outputs the packet reception signal received from the other wireless communication device 50 to the receiving unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the communication control unit 64.

  The communication control unit 64 acquires information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 for every beam direction based on the demodulation result of the packet reception signal of the reception unit 63 and stores the information in the memory ( By storing in (not shown), the SN for each beam direction is acquired.

  Next, in step S <b> 7, the communication control unit 64 acquires information indicating the communication characteristics for every beam direction, and then there is a beam direction in which communication is possible between the terminal device 60 and the other wireless communication device 50. It is determined whether or not. If the communication control unit 64 determines that there is a beam direction in which communication is possible between the terminal device 60 and the other wireless communication device 50 (S7, YES), the beam direction of the circularly polarized wave radiated by the antenna unit 61 is determined. Switching to the beam direction in which the best communication characteristics are obtained, and communication with the other wireless communication device 50 is continued.

  The communication control unit 64 uses, for example, a timer to determine whether or not a certain time has elapsed since the beam direction of the circularly polarized wave radiated from the antenna unit 61 is switched to the beam direction in which the best communication characteristics are obtained. (S9). If the predetermined time has not elapsed (S9, NO), the communication operation procedure of the terminal device 60 returns to step S5.

  On the other hand, when the predetermined time has elapsed (S9, YES), the communication operation procedure of the terminal device 60 returns to step S1. Here, the condition for the communication operation procedure of the terminal device 60 to return to step S1 has been described as a case where a fixed time has elapsed in step S9. However, for example, at the timing when the terminal device 60 detects a packet loss, the step The communication operation order of S1 may be executed.

  Here, the reason for returning to the communication operation procedure in step S1, that is, the communication operation procedure for specifying the antenna shape of the other wireless communication device 50 when a certain time has passed in step S9 is as follows.

  Specifically, at the time when the specific operation procedure of the antenna shape of the other wireless communication device 50 is executed, an obstacle 54 (see FIG. 4C) is mixed between the terminal device 60 and the other wireless communication device 50. In this case, the terminal device 60 and the other wireless communication device 50 communicate using the reflected wave (see reference numeral 51b shown in FIG. 4C).

  Originally, it is desirable to communicate using the direct wave having the best communication characteristics (see the communication path 51a shown in FIG. 4A). However, if the communication using the reflected wave continues, the terminal device 60 and other wireless communication are performed. Communication characteristics with the device 50 are degraded as compared with direct waves.

  Therefore, when a predetermined time has elapsed in step S9, the reflected wave (shown in FIG. 4C) returns to the communication operation procedure in step S1, that is, the communication operation procedure for specifying the antenna shape of the other wireless communication device 50. Even when the communication using the communication path 51b is continued, for example, assuming that the obstacle 54 is removed, the terminal device 60 and the other wireless communication device 50 are connected to the direct wave (shown in FIG. 4A). This is to obtain an opportunity to switch to communication using the communication path 51a).

  In addition, when a fixed time passes in step S9, it is not necessary to return to the communication operation procedure of step S1, that is, the communication operation procedure for specifying the antenna shape of the other wireless communication device 50. For example, the communication control unit 64 may transmit a packet transmission signal for obtaining communication characteristics from the antenna unit 61 by using circular polarization in a turning direction opposite to the turning direction in communication for each beam direction. The same applies to the following embodiments.

  Thereby, even when the terminal device 60 moves during the communication between the terminal device 60 and the other wireless communication device 50, the communication control unit 64 sets the communication characteristics between the terminal device 60 and the other wireless communication device 50. It is possible to monitor in real time and avoid packet loss when the terminal device 60 moves.

2. When an obstacle 54 is mixed between the terminal device 60 and the other wireless communication device 50. Next, during communication between the terminal device 60 and the other wireless communication device 50, between the terminal device 60 and the other wireless communication device 50. A communication operation procedure of the terminal device 60 when the obstacle 54 is mixed into the terminal device 60 (see FIG. 4C) will be described.

  When the terminal device 60 and the other wireless communication device 50 are communicating using the communication path 51a (see FIG. 4A) and the obstacle 54 is mixed, the packet transmission signal transmitted by the terminal device 60 is transmitted to the other wireless device. It does not reach the communication device 50 (see FIG. 4C).

  Therefore, the communication control unit 64 determines in step S7 shown in FIG. 6 that there is no beam direction in which communication is possible between the terminal device 60 and the other wireless communication device 50 (S7, NO).

  The communication control unit 64 interrupts the transmission of the packet transmission signal using the right-turning circularly polarized wave switched in step S5. Further, the communication control unit 64 switches the circularly polarized turning direction radiated by the antenna unit 61 to the reverse leftward turning direction, and further instructs the antenna switching unit 66 to switch the circularly polarized beam direction in the leftward turning direction. In addition, a communication characteristic acquisition request for requesting communication characteristics with the other wireless communication device 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the turning direction of the circularly polarized wave radiated from the antenna unit 61 to the left turning direction, and further switches the beam direction of the circularly polarized wave in the left turning direction. An antenna switching control signal is generated and output to the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmission unit 62 for each beam direction using the circularly polarized wave in the left turn direction.

  When the obstacle 54 is mixed between the terminal device 60 and the other wireless communication device 50, the other wireless communication device 50 receives the packet transmission signal transmitted by the terminal device 60 through the communication path 51b.

  The other radio communication device 50 communicates the packet transmission signal transmitted by using the circularly polarized wave in the right turn direction and reflected by the ground once and switched to the circularly polarized wave in the left turn direction. Receive via path 51b. The other radio communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60 using the circularly polarized wave in the right turn direction.

  The terminal device 60 transmits the packet transmission signal transmitted by using the circularly polarized wave in the clockwise direction to the circularly polarized wave in the counterclockwise direction after the packet transmitted signal is reflected once on the ground, and the communication path 51b. Receive by.

  The terminal device 60 outputs the packet reception signal received from the other wireless communication device 50 to the receiving unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the communication control unit 64.

  The communication control unit 64 re-acquires information indicating the communication characteristics between the terminal device 60 and the other radio communication device 50 based on the demodulation result of the packet reception signal of the reception unit 63 for every beam direction and stores the memory. (S8). The communication control unit 64 switches the beam direction of the circularly polarized wave in the left-turning direction to a beam direction with the best communication characteristics between the terminal device 60 and the other wireless communication device 50, and communicates with the other wireless communication device 50. Communication between the two. In addition, since the operation | movement of the terminal device 60 after step S8 is the same as the description mentioned above, description is abbreviate | omitted.

  As a result, even when the obstacle 54 is mixed during communication between the terminal device 60 and the other wireless communication device 50, the communication control unit 64 uses the reflected wave instead of the direct wave, so that the communication characteristics are the best. It is possible to continue communication by switching to a different beam direction.

  FIG. 10A is a table simply showing an example of a result of communication characteristics for each regular beam direction during communication when the other wireless communication apparatus 50 has a circularly polarized antenna. Note that FIG. 10 describes the case where the beam direction is 16 directions. The beam directions are not limited to the four directions shown in FIG. 4 and the 16 directions shown in FIG. 10, and any number can be used.

  FIG. 10A shows the result of switching (scanning) the beam directions of circularly polarized waves in both turning directions from beam numbers 1 to 16 during the communication a predetermined time before the present time. The communication characteristic in the beam direction corresponding to the circularly polarized beam No. 1 in the rotational direction was the best (see the left side of the arrow shown in FIG. 10A).

  In FIG. 10A, the terminal device 60 can specify that the antenna shape of the other wireless communication device 50 is a circularly polarized antenna in the right turn direction, so that the best communication is currently performed during a predetermined time ago communication. Switching to the right turn direction and the beam direction in which the characteristics are obtained is performed, and the communication characteristics with the other wireless communication device 50 are acquired. In FIG. 10A, the communication characteristic in the beam direction corresponding to the beam number 15 using the circularly polarized wave in the clockwise direction is the best (see the right side of the arrow shown in FIG. 10A).

  Since the beam direction in which the best communication characteristic is obtained without changing the turning direction of the circularly polarized wave is different, the terminal device 60 can detect the movement of the terminal device 60 itself, and not the both turning directions but the one turning direction ( For example, the beam direction in the circularly polarized wave in the clockwise direction shown in FIG.

  As a result, the terminal device 60 can specify that the antenna shape of the other wireless communication device 50 is a circularly polarized antenna in the right turn direction, so that it is not in both turn directions but in one turn direction (for example, in FIG. 10A). By scanning the beam direction of the circularly polarized wave (right-turning direction), it is possible to reduce power consumption required for acquiring communication characteristics with the other wireless communication device 50.

  FIG. 10B is a table simply showing an example of the result of the communication characteristics for each beam direction after the communication is cut off when the other wireless communication device 50 has a circularly polarized antenna.

  In FIG. 10B, before the obstacle 54 is mixed, that is, before the communication is interrupted, the beam directions of the circularly polarized waves in both turning directions are switched (scanned) to the beam numbers 1 to 16, and as a result The communication characteristic in the beam direction corresponding to the beam number 1 of the circularly polarized wave in the turning direction was the best (see the left side of the arrow shown in FIG. 10B).

  In FIG. 10B, the terminal device 60 can specify that the antenna shape of the other radio communication device 50 is a circularly polarized antenna in the right-turn direction, so that the best communication is currently performed during a predetermined time ago communication. Switching to the right turn direction and the beam direction in which the characteristics are obtained is performed, and the communication characteristics with the other wireless communication device 50 are acquired. In FIG. 10B, the communication characteristics in the beam direction using the circularly polarized wave in the right turn direction were not good (see the right side of the arrow shown in FIG. 10B).

  Therefore, the terminal device 60 switches the turning direction of the circular polarization to the left turning direction, and similarly acquires the communication characteristics with the other wireless communication device 50 for every beam direction. In FIG. 10B, the communication characteristic in the beam direction corresponding to the beam number 15 using the circularly polarized wave in the left turn direction is the best (see the right side of the arrow shown in FIG. 10B).

  In other words, in FIG. 10B, the circularly polarized wave (right turning direction) and beam that are completely different from the circularly polarized wave (right turning direction) and beam direction (beam number 1) having the best communication characteristics in step S1 are shown. The communication characteristics in the direction (beam number 15) were the best. For this reason, the terminal device 60 can detect that the obstacle 54 is mixed, and scans the beam direction in the circularly polarized wave in both turning directions.

  FIG. 11 is a comparison diagram of the number of times the beam direction is scanned in order to acquire the communication characteristics after the communication is interrupted in the related art and the first embodiment. In FIG. 11, the beam direction in which the circularly polarized wave in the single-turn direction is radiated is 16 directions. The beam directions are not limited to the four directions shown in FIG. 4 and the 16 directions shown in FIG. 11, and any number can be used.

  In this embodiment, communication between the other wireless communication device 50 having a linearly polarized antenna and the terminal device 60 having a circularly polarized antenna is interrupted when the terminal device 60 moves or when an obstacle 54 is mixed. In any case, the number of scans in the beam direction in the terminal device 60 is 16, which is halved compared to 32 times in the prior art.

  This is because there is no difference in communication characteristics depending on the turning direction of the circular polarization of the terminal device 60 in the combination in which the terminal device 60 is circularly polarized and the other wireless communication device 50 is linearly polarized. This is because the beam direction may be scanned in the turning direction.

  In addition, when communication between the other wireless communication device 50 having the circularly polarized antenna and the terminal device 60 having the circularly polarized antenna is interrupted due to the obstacle 54 being mixed, scanning of the beam direction in the terminal device 60 is performed. The number of times is 32 times, which is the same as that of the prior art, but when the terminal device 60 moves, the number of times of scanning in the beam direction in the terminal device 60 is 16, which is halved compared to 32 times of the prior art. Thus, the power consumption in the terminal device 60 is reduced by the reduction in the number of scans in the beam direction in the terminal device 60.

  The flowchart of FIG. 6 mainly describes the operation of the terminal device 60, but the operation in which the other wireless communication device 50 acquires the SN for each beam direction before step S1, after step S1, or after step S2. May be performed.

  For example, the other wireless communication device 50 performs the operation of Step S1 performed by the terminal device 60 on the other wireless communication device 50 after S1 of FIG.

  Thereby, the terminal device 60 and the other radio | wireless communication apparatus 50 can know the optimal beam direction, respectively.

  As described above, the terminal device 60 according to the present embodiment identifies the antenna shape of the other wireless communication device 50 as a communication partner when the communication is interrupted regularly or when the communication is interrupted, and the polarization emitted from the antenna of the other wireless communication device 50 In consideration of the above, the communication characteristics with the other wireless communication device 50 are acquired by switching the polarization and the beam direction.

  Thereby, the terminal device 60 can continue the communication by switching to the polarization and beam direction in which the best communication characteristics are obtained in the communication between the terminal device 60 and the other wireless communication device 50. Further, since the terminal device 60 can simplify the operation required for switching the polarization and beam direction even when the terminal device 60 moves or an obstacle 54 is mixed, the antenna shape of the other wireless communication device 50 is circular. If it is not a polarization antenna, the power consumption in the terminal device 60 can be reduced.

(Second Embodiment)
In the first embodiment, when specifying the antenna shape of the other wireless communication device 50, the terminal device 60 radiates using circular polarization in the left turn direction and circular polarization in the right turn direction. Also in communication with the wireless communication device 50, radiation was performed using circularly polarized waves.

  In the second embodiment, when specifying the antenna shape of the other radio communication device 50, the terminal device 60 radiates using linearly polarized waves (for example, vertical polarization and horizontal polarization), and the other radio communication device 50. Depending on the antenna shape, the linearly polarized wave and the circularly polarized wave are switched and radiated.

  Since the terminal device 60 of the present embodiment has the same configuration as the terminal device 60 shown in FIG. 1, the same components as those of the terminal device 60 of the first embodiment will be described using the same reference numerals. Omitted or simplified, different contents will be described.

  When the antenna shape of the other wireless communication apparatus 50 is specified as a linearly polarized antenna, the antenna detector 65 determines whether the linearly polarized wave radiated from the linearly polarized antenna is horizontal polarized wave or vertical polarized wave. Determine if it exists. The antenna detection unit 65 outputs the linear polarization type identification result to the communication control unit 64 or the antenna switching unit 66.

  Note that when the antenna detection unit 65 specifies that the antenna shape of the other radio communication device 50 is a linearly polarized antenna, the terminal device 60 uses circular polarization, and thus the other radio communication device 50 has a horizontal polarization. The identification of whether it is a wave or a vertically polarized wave can be omitted.

  FIG. 12 is a diagram illustrating a circuit configuration of a polarization antenna 71C according to the second embodiment. A polarization antenna 71 </ b> C illustrated in FIG. 12 includes a two-terminal-feed circular polarization antenna 91, a 90-degree phase shifter 92, a 180-degree hybrid 93, and a switch 95.

  In the first embodiment, the 90-degree phase shifter 92 switches the polarity of the phase difference of 90 degrees (for example, +90 degrees or -90 degrees) in accordance with the antenna switching control signal generated by the antenna switching unit 66, and the circle The direction of polarization rotation was switched. In this embodiment, it is not necessary to switch the direction of circular polarization of the circularly polarized wave, that is, the terminal device 60 may use either the left-turned or right-handed circularly polarized wave when emitting circularly polarized light. Therefore, the 90-degree phase shifter 92 uses one of the polarities with a phase difference of 90 degrees (for example, +90 degrees).

  The switch 95 includes a switch 95a and a switch 95b. The switch 95a switches the connection between the input / output terminal 91a of the two-terminal-feed type circularly polarized antenna 91 and the input / output terminal 93c of the 180-degree hybrid 93 on or off. The switch 95b switches the connection between the input / output terminal 91b of the two-terminal-feed type circularly polarized antenna 91 and the 90-degree phase shifter 92 on or off.

  The polarization antenna 71C shown in FIG. 12 can switch the polarization radiated by the antenna unit 61 to circular polarization or linear polarization by switching the switches 95a and 95b on or off.

  Specifically, when both the switches 95a and 95b are turned on, the polarization antenna 71C is turned left or right from the two-terminal-feed circular polarization antenna 91 as in the first embodiment. Of circularly polarized waves.

  The polarization antenna 71C radiates linearly polarized waves from the two-terminal-feed circularly polarized antenna 91 in a combination in which the switch 95a is on and the switch 95b is off, or a combination in which the switch 95a is off and the switch 95b is on.

  In the two-terminal feed type circularly polarized wave antenna 91, each position on the x-axis and the y-axis that is the same distance away from the center of the patch antenna is fed. Therefore, in the polarization antenna 71C, the polarization direction radiated from the input / output terminals 91a and 91b is a combination of the switch 95a on and the switch 95b off and the combination of the switch 95a off and the switch 95b on. Are radiated as vertical polarization or horizontal polarization, which are 90 degrees apart from each other.

  Note that the polarization antenna 71C may have a configuration other than that shown in FIG. 12 as long as switching between linear polarization and circular polarization is possible, and the two-terminal feed type circular polarization antenna 91, 90-degree phase shifters 92, 180. You may comprise using elements other than degree hybrid 93 and switch 95. FIG.

(Communication operation procedure of terminal device 60)
Next, a communication operation procedure in the terminal device 60 of the present embodiment will be described with reference to FIG. FIG. 13 is a flowchart illustrating a communication processing procedure in the terminal device 60 according to the second embodiment. In the description of FIG. 13, the antenna unit 61 of the terminal device 60 radiates linearly polarized vertical polarization and horizontal polarization.

  In FIG. 13, the communication control unit 64 determines that the antenna shape of the other wireless communication device 50, that is, the antenna of the other wireless communication device 50, before wireless communication between the terminal device 60 and the other wireless communication device 50 is started. The type of polarized wave to be radiated is specified (see FIG. 14). Specifically, the communication control unit 64 causes the antenna switching unit 66 to switch the polarization plane (vertical polarization or horizontal polarization) and beam direction of the linearly polarized wave radiated from the antenna unit 61, and linear polarization of both polarization planes. Communication characteristics for each beam direction in the wave are acquired (S31).

(Specific operation procedure of antenna shape of other wireless communication device 50)
FIG. 14 is a flowchart illustrating an operation procedure for specifying the antenna shape of the other wireless communication device 50 in step S31 shown in FIG.

  In FIG. 14, the communication control unit 64 outputs, for example, an instruction to switch the linearly polarized wave radiated by the antenna unit 61 to the vertically polarized wave, and further switches the beam direction of the vertically polarized wave to the antenna switching unit 66. A communication characteristic acquisition request for requesting communication characteristics with the communication device 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the linearly polarized wave radiated from the antenna unit 61 to the vertical polarization, and further generates an antenna switching control signal for switching the beam direction of the vertical polarization. To the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmission unit 62 for every beam direction using vertical polarization (S41).

  When the other wireless communication device 50 receives a packet transmission signal transmitted using vertical polarization, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 receives a packet reception signal from the other wireless communication device 50 (S42, YES), the terminal device 60 outputs the packet reception signal to the reception unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the antenna detection unit 65.

  The antenna detection unit 65 stores information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 in a memory (not shown) for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63. (S43). That is, the antenna detection unit 65 stores information indicating communication characteristics for all beam directions in the case where vertical polarization is used, and the communication control unit 64 performs the following operation, that is, all in the case where horizontal polarization is used. The acquisition of information indicating communication characteristics for each beam direction is instructed.

  On the other hand, if no reply is received from the other wireless communication device 50 after a certain period of time has elapsed since the terminal device 60 transmitted the packet transmission signal for each beam direction (S42, NO), the antenna detection unit 65 returns the reply. Is stored for each corresponding beam direction (S44), and the communication controller 64 indicates the next operation, that is, the communication characteristics for each beam direction when horizontal polarization is used. Instructs the acquisition of information.

  Next, the communication control unit 64 switches the linearly polarized wave radiated from the antenna unit 61 to the horizontal polarization, and further outputs an instruction to switch the beam direction of the horizontal polarization to the antenna switching unit 66. 50, a communication characteristic acquisition request for requesting the communication characteristic with 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the linearly polarized wave radiated from the antenna unit 61 to the horizontal polarization, and further generates an antenna switching control signal for switching the beam direction of the horizontal polarization. To the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmitting unit 62 for every beam direction using horizontal polarization (S45).

  When receiving the packet transmission signal transmitted using the horizontally polarized wave, the other radio communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 receives a packet reception signal from the other wireless communication device 50 (S46, YES), the terminal device 60 outputs the packet reception signal to the reception unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the antenna detection unit 65.

  The antenna detection unit 65 stores information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 in a memory (not shown) for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63. (S47). That is, the antenna detection unit 65 stores information indicating communication characteristics for all beam directions when horizontal polarization is used. Thereby, the specific operation procedure of the antenna shape of the other radio communication device 50 shown in FIG. 14 is ended, and the communication operation procedure of the terminal device 60 returns to step S32 of the flowchart shown in FIG.

  On the other hand, if no response is received from another wireless communication device 50 after a certain time has elapsed since the terminal device 60 transmits a packet transmission signal for each beam direction (S46, NO), the antenna detection unit 65 returns the response. There is no information, i.e., information indicating that the beam has not been received, for each corresponding beam direction (S48). Thereby, the specific operation procedure of the antenna shape of the other radio communication device 50 shown in FIG. 14 is ended, and the communication operation procedure of the terminal device 60 returns to step S32 of the flowchart shown in FIG.

  In FIG. 14, the terminal device 60 first radiates vertical polarization and then radiates horizontal polarization. However, the linear polarization may be radiated in the order of vertical polarization or horizontal polarization first.

  In FIG. 13, the antenna detection unit 65 compares information indicating communication characteristics for each beam direction when vertical polarization is used with information indicating communication characteristics for each beam direction when horizontal polarization is used. (S32).

  The antenna detector 65 is based on a comparison result between information indicating communication characteristics for each beam direction when using vertical polarization and information indicating communication characteristics for each beam direction when using horizontal polarization. It is specified whether the antenna shape of the other wireless communication device 50 is a circularly polarized antenna or a linearly polarized antenna (see FIG. 15).

  FIG. 15 is a table showing a comparison result of the polarization radiated from the antenna of the other wireless communication device 50 when the terminal device 60 uses linear polarization. In FIG. 15, the best communication is achieved when the terminal device 60 uses linearly polarized vertical and horizontal polarized waves, and the other radio communication device 50 switches the beam direction using linearly polarized waves and circularly polarized waves. The comparison result of the beam direction from which the characteristic was obtained is shown. The numerical value (for example, 2) shown in FIG. 15 represents the beam number in the beam direction in which the best communication characteristics are obtained (see FIG. 4).

  Specifically, the antenna detection unit 65 has a communication characteristic difference between the terminal device 60 and the other wireless communication device 50 in the case where vertical polarization and horizontal polarization are used, or is the most When the beam numbers in the beam direction in which good communication characteristics are obtained are the same (see column 504 shown in FIG. 15), it is specified that the antenna shape of other wireless communication device 50 is a circularly polarized antenna.

  Theoretically, power is halved when horizontal polarization is received by circular polarization and when vertical polarization is received by circular polarization (see FIG. 5). This is because the same communication characteristic is received for both vertically polarized waves.

  On the other hand, the antenna detection unit 65 obtains the best communication characteristics in which the difference in communication characteristics between the terminal device 60 and the other wireless communication device 50 when vertical polarization and horizontal polarization are used is not within a predetermined range. If the beam numbers in the different beam directions are different (see column 503 shown in FIG. 15) or there is no response to radiation of vertical polarization or horizontal polarization, the antenna shape of the other radio communication device 50 is a linearly polarized antenna. Is identified.

  This is because if the polarization planes of the linearly polarized waves of the terminal device 60 and the other wireless communication device 50 are different, the communication characteristics are greatly different, and communication with each other is poor (see FIG. 5).

  When the other wireless communication device 50 returns a packet reception signal including information on the beam direction in which the best communication characteristics are obtained to the terminal device 60, the other wireless communication device 50 transmits the linearly polarized antenna and the circularly polarized wave. If the beam direction in which the best communication characteristic is obtained is the same regardless of which of the antennas is used, it may be difficult for the terminal device 60 to specify the antenna shape of the other wireless communication device 50.

  Therefore, the terminal device 60 measures received power using RSSI (Received Signal Strength Indication), and transmits using the received power of the packet reception signal transmitted using linearly polarized waves and circularly polarized waves. When the received power of the received packet signal is different, the antenna shape of the other wireless communication device 50 is specified as a linearly polarized antenna.

  When the reception power of the packet reception signal transmitted using linear polarization and the reception power of the packet reception signal transmitted using circular polarization are the same, the terminal device 60 of the other radio communication device 50 The antenna shape is identified as a circularly polarized antenna. Thereby, the terminal device 60 can easily specify the antenna shape of the other wireless communication device 50.

  The antenna detection unit 65 specifies the antenna shape of the other wireless communication device 50, and then outputs the specification result to the communication control unit 64. The communication control unit 64 instructs the antenna switching unit 66 to switch the polarization (circular polarization, linear polarization) and the beam direction in accordance with the result of specifying the antenna shape of the other radio communication device 50, and Communication with another wireless communication device 50 is started.

(Communication operation procedure when other wireless communication device 50 has a linearly polarized antenna)
The communication control unit 64 determines that the antenna unit 61 of the terminal device 60 radiates when the antenna shape of the other radio communication device 50 is determined to be a linearly polarized antenna by the process in step S31 (S32, YES). Switch the wave from linear polarization to circular polarization. In addition, since the other radio | wireless communication apparatus 50 is a linearly polarized antenna, the turning direction to be used may be either right or left.

  Note that even if the antenna polarization is switched, the SN for each beam direction does not change, so the beam direction to be used may use the direction obtained in step S1, but in the case of circular polarization, from FIG. The SN is measured again for each beam direction in consideration of communication failure due to the reception power being reduced by half.

  That is, the terminal device 60 switches the polarization radiated by the antenna unit 61 from the linearly polarized wave to the circularly polarized wave, and acquires the communication characteristics between the terminal device 60 and the other wireless communication device 50 for every beam direction. Then, communication with the other wireless communication device 50 is started using the beam direction in which the best communication characteristics are obtained (S32-1). In addition, when there is no more communicable beam by switching to the circularly polarized antenna, the terminal device 60 has good communication characteristics among horizontal polarization and vertical polarization in consideration of the result of step S31. Communication is started using polarized waves (S32-1).

  When the terminal device 60 moves during communication between the terminal device 60 and the other wireless communication device 50 (see FIG. 4B), or between the terminal device 60 and the other wireless communication device 50, the obstacle 54 Since the operation of steps S33 and S34, which is the communication operation procedure of the terminal device 60 in the case of mixing (see FIG. 4C), is the same as the operation of steps S3 and S4 shown in FIG. To do.

(Processing when other wireless communication device 50 has a circularly polarized antenna)
When the communication control unit 64 determines that the antenna shape of the other wireless communication device 50 is a circularly polarized antenna (S32, NO), the communication control unit 64 considers the result of step S31 and determines whether the polarization is horizontal polarization or vertical polarization. Communication is started using polarized waves with good communication characteristics.

  For example, the linear polarization plane of radiation radiated from the antenna unit 61 is switched to horizontal polarization, and further an instruction to switch the beam direction of the horizontal polarization is output to the antenna switching unit 66 to start communication (S32-2).

Next, when the terminal device 60 moves during communication between the terminal device 60 and the other wireless communication device 50 (see FIG. 4B) or when an obstacle 54 is mixed (see FIG. 4C). A communication operation procedure of the terminal device 60 will be described.
A communication characteristic acquisition request for requesting communication characteristics with another wireless communication device 50 is generated and output to the transmission unit 62.

  In response to an instruction from the communication control unit 64, the antenna switching unit 66 switches the polarization plane of the linearly polarized wave radiated from the antenna unit 61 to the vertical polarization, and further switches the beam direction of the vertical polarization. Is output to the antenna unit 61.

  In response to the communication characteristic acquisition request generated by the communication control unit 64, the transmission unit 62 generates, for example, a packet transmission signal for requesting communication characteristics with the other wireless communication device 50 and outputs the packet transmission signal to the antenna unit 61. . In response to the antenna switching control signal generated by the antenna switching unit 66, the antenna unit 61 transmits the packet transmission signal generated by the transmission unit 62 for every beam direction using vertical polarization (S35).

  When the terminal device 60 moves, the other wireless communication device 50 receives the packet transmission signal transmitted by the terminal device 60 through the communication paths 52a and 52b. Further, when the obstacle 54 is mixed between the terminal device 60 and the other wireless communication device 50, the other wireless communication device 50 receives the packet transmission signal transmitted by the terminal device 60 through the communication path 51b.

  When the other wireless communication device 50 receives a packet transmission signal transmitted using vertical polarization, the other wireless communication device 50 returns a packet reception signal including information indicating communication characteristics for each beam direction to the terminal device 60.

  When the terminal device 60 moves, the terminal device 60 receives the packet transmission signal transmitted by the other wireless communication device 50 through the communication paths 52a and 52b. Further, when the obstacle 54 is mixed between the terminal device 60 and the other wireless communication device 50, the terminal device 60 receives the packet reception signal transmitted by the other wireless communication device 50 through the communication path 51b.

  The terminal device 60 outputs the packet reception signal received from the other wireless communication device 50 to the receiving unit 63 via the antenna unit 61. The receiving unit 63 demodulates the packet reception signal output from the antenna unit 61 and outputs the demodulation result of the packet reception signal to the communication control unit 64.

  The communication control unit 64 acquires information indicating communication characteristics between the terminal device 60 and the other wireless communication device 50 for each beam direction based on the demodulation result of the packet reception signal of the reception unit 63 and stores the information in a memory (not shown). ).

  The communication control unit 64 switches the direction of the vertically polarized beam radiated from the antenna unit 61 to the beam direction in which the best communication characteristics are obtained, and continues communication with the other wireless communication device 50 (S36). ).

  The communication control unit 64 uses, for example, a timer to determine whether or not a predetermined time has elapsed since the beam direction of the vertically polarized wave radiated from the antenna unit 61 is switched to the beam direction in which the best communication characteristics are obtained. (S37). If the predetermined time has not elapsed (S37, NO), the communication operation procedure of the terminal device 60 returns to step S35.

  On the other hand, when the fixed time has elapsed (S37, YES), the communication operation procedure of the terminal device 60 returns to step S31.

  Here, the reason for returning to the communication operation procedure in step S31, that is, the communication operation procedure for specifying the antenna shape of the other wireless communication device 50 when a predetermined time has passed in step S37 is as follows.

  Specifically, at the time when the communication operation procedure for specifying the antenna shape of the other wireless communication device 50 is executed, the antenna shape of the other wireless communication device 50 depends on the positions of the terminal device 60 and the other wireless communication device 50. This is because the terminal device 60 may specify the antenna shape of the other wireless communication device 50 as a circularly polarized antenna, although it is a linearly polarized antenna.

  For example, when the terminal device 60 and the other wireless communication device 50 do not exist at positions facing each other but exist in a direction shifted by 45 degrees with respect to the horizontal direction, the terminal device 60 has a circularly polarized antenna, The packet reception signal whose reception power is halved is received from the other radio communication device 50 regardless of whether the other radio communication device 50 radiates by either vertical polarization or horizontal polarization.

  In the prior art, once the terminal device 60 identifies the antenna shape of the other radio communication device 50 as a circularly polarized antenna, the terminal device 60 does not identify the antenna shape of the other radio communication device 50 again. It is difficult to execute the communication operation procedure using.

  As described above, the terminal device 60 of the present embodiment can monitor the communication characteristics with the other wireless communication device 50 and can avoid packet loss. Since the terminal device 60 radiates using the linearly polarized wave when the other radio communication device 50 is identified as having a circularly polarized antenna, the presence or absence of the obstacle 54 with the other radio communication device 50 is determined. Regardless, communication characteristics can be acquired.

  As a result, the terminal device 60 only needs to transmit a packet transmission signal for requesting communication specification to one of the planes of linear polarization (for example, vertical polarization or horizontal polarization). Power consumption required for switching can be reduced.

  FIG. 16 is a comparison diagram of the number of times the beam direction is scanned in order to acquire the communication characteristics after the communication is interrupted in the related art and the second embodiment. In FIG. 16, the beam direction in which the circularly polarized wave in the one-turn direction is emitted is 16.

  In the present embodiment, the communication between the other wireless communication device 50 having the linearly polarized antenna and the terminal device 60 is performed both when the terminal device 60 moves and when the obstacle 54 is mixed and the communication is interrupted. The number of scans in the beam direction in the apparatus 60 is 16, which is halved compared to 32 in the prior art.

  In addition, communication between the other wireless communication device 50 having the circularly polarized antenna and the terminal device 60 is performed in the terminal device 60 both when the terminal device 60 moves and when the obstacle 54 is mixed and communication is interrupted. The number of scans in the beam direction is 16, which is halved compared to 32 times in the prior art.

  Thus, the power consumption in the terminal device 60 is reduced by the reduction in the number of scans in the beam direction in the terminal device 60.

  As described above, the terminal device 60 according to the present embodiment identifies the antenna shape of the other wireless communication device 50 as a communication partner when the communication is interrupted regularly or when the communication is interrupted, and the polarization emitted from the antenna of the other wireless communication device 50 In consideration of the above, the communication characteristics with the other wireless communication device 50 are acquired by switching the polarization and the beam direction.

  As mentioned above, although various embodiment was described with reference to drawings, it cannot be overemphasized that this indication is not limited to this example. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present disclosure. Understood.

  For example, in each of the above-described embodiments, the case where the two-terminal feeding antenna is four elements has been described, but the number of elements is not limited to four elements. In addition, as the circularly polarized antenna, the two-terminal-feed type circularly polarized patch antenna shown in FIG. 2 is taken as an example, but is not limited thereto.

  Further, in each of the above-described embodiments, the antenna unit 61 assigns each circularly polarized antenna for the left turn direction or the right turn direction to each antenna element, and outputs the antenna switching control signal generated by the antenna switching unit 66. Accordingly, a desired antenna element may be used.

  Examples of the terminal device 60 include a smartphone, a tablet terminal, and a remote controller that are mobile devices that can be carried by the user. The terminal device may be a stationary device. The other wireless communication device 50 may be a stationary device such as a TV, a display device, or a PC (Personal Computer). The wireless communication device may be a mobile device that can be carried by the user.

  Furthermore, in the first embodiment described above, the terminal device 60 uses the circularly polarized wave in the right turn direction, and sequentially switches the beam direction, so that the communication characteristics between the terminal device 60 and the other wireless communication device 50 are changed. For example, if the number of beam directions is 16 at the maximum (see FIG. 9), the communication characteristics are obtained when the best communication characteristics are obtained before the end of scanning (switching) 16 beam directions. The acquisition request may be canceled and the communication may be continued by switching to the beam direction in which the best communication characteristics are obtained.

  Thereby, the terminal device 60 can further reduce the power consumption required for scanning (switching) in the beam direction.

  The present disclosure acquires communication characteristics with another wireless communication device as a communication partner periodically or when communication is interrupted, and the polarization radiated by the antenna is biased according to good communication characteristics. It is useful as an antenna switching device that easily switches to a wave.

50 Other wireless communication device 60 Terminal device 61, 61A, 61B Antenna unit 62 Transmission unit 63 Reception unit 64 Communication control unit 65 Antenna detection unit 66 Antenna switching unit

Claims (8)

An antenna switching device that wirelessly communicates with other wireless communication devices,
An antenna unit that switches the polarization and beam direction in the wireless communication and radiates the polarization in the beam direction with respect to the other wireless communication device;
A communication control unit that acquires communication characteristics according to the polarization and the beam direction from the other wireless communication device;
Based on the communication characteristics corresponding to the acquired polarization and the beam direction, the type of polarization antenna of the other radio communication apparatus is radiated identify whether it is of circular polarization or linear polarization An antenna detector to perform,
An antenna switching unit that switches polarization and beam direction in wireless communication with the other wireless communication device according to the type of polarization emitted by the antenna of the specified other wireless communication device;
Antenna switching device. The antenna switching device according to claim 1,
The antenna unit is
Radiate circularly polarized waves in the left or right turn direction,
The antenna detector is
When the communication characteristics of each circularly polarized wave in the left turn direction and the right turn direction are within a predetermined range, the type of polarization radiated by the antenna of the other wireless communication device is identified as a linear polarization ,
When the communication characteristics of each circularly polarized wave in the left turn direction and the right turn direction are not within the predetermined range, the type of polarization emitted by the antenna of the other wireless communication device is specified as a circularly polarized wave .
Antenna switching device. The antenna switching device according to claim 2,
The antenna detector is
The type of polarization emitted by the antenna of the other wireless communication device is identified as linear polarization ,
The antenna switching unit is
When the wireless communication is in communication or when the wireless communication is interrupted, the antenna unit radiates circular polarization in the left turn direction or the right turn direction used during the communication.
Antenna switching device. The antenna switching device according to claim 2,
The antenna detector is
The type of polarization emitted by the antenna of the other wireless communication device is identified as circular polarization ,
The antenna switching unit is
When the wireless communication is in communication or when the wireless communication is interrupted, the antenna unit radiates circular polarization in the left turn direction or the right turn direction used during the communication.
Antenna switching device. The antenna switching device according to claim 4,
The antenna switching unit is
The left turn direction or the right turn direction used during the communication when the communication characteristic acquired according to the emitted circularly polarized wave in the left turn direction or the right turn direction is less than a predetermined value. Radiate the circularly polarized wave in the direction opposite to the circularly polarized wave to the antenna unit,
Antenna switching device. The antenna switching device according to claim 1,
The antenna unit is
Radiates horizontal polarization with horizontal polarization plane or vertical polarization with vertical polarization plane,
The antenna detector is
When the communication characteristics in the horizontal polarization and the vertical polarization are within a predetermined range, the type of polarization emitted by the antenna of the other wireless communication device is specified as circular polarization ,
When the communication characteristics in the horizontal polarization and the vertical polarization are not within the predetermined range, the type of polarization radiated by the antenna of the other wireless communication device is specified as linear polarization ,
Antenna switching device. The antenna switching device according to claim 6, wherein
The antenna detector is
The type of polarization emitted by the antenna of the other wireless communication device is identified as linear polarization ,
The antenna switching unit is
Radiating the horizontal polarization or the vertical polarization used during the communication to the antenna unit during communication of the wireless communication or when the wireless communication is interrupted,
Antenna switching device. The antenna switching device according to claim 6, wherein
The antenna detector is
The type of polarization emitted by the antenna of the other wireless communication device is identified as circular polarization ,
The antenna switching unit is
Radiating the horizontally polarized wave or the vertically polarized wave to the antenna unit during communication of the wireless communication or when the wireless communication is interrupted,
Antenna switching device.

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